CN108933277A - A kind of lithium ion secondary battery - Google Patents
A kind of lithium ion secondary battery Download PDFInfo
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- CN108933277A CN108933277A CN201710365119.2A CN201710365119A CN108933277A CN 108933277 A CN108933277 A CN 108933277A CN 201710365119 A CN201710365119 A CN 201710365119A CN 108933277 A CN108933277 A CN 108933277A
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/05—Accumulators with non-aqueous electrolyte
- H01M10/056—Accumulators with non-aqueous electrolyte characterised by the materials used as electrolytes, e.g. mixed inorganic/organic electrolytes
- H01M10/0564—Accumulators with non-aqueous electrolyte characterised by the materials used as electrolytes, e.g. mixed inorganic/organic electrolytes the electrolyte being constituted of organic materials only
- H01M10/0566—Liquid materials
- H01M10/0569—Liquid materials characterised by the solvents
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/05—Accumulators with non-aqueous electrolyte
- H01M10/052—Li-accumulators
- H01M10/0525—Rocking-chair batteries, i.e. batteries with lithium insertion or intercalation in both electrodes; Lithium-ion batteries
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M2300/00—Electrolytes
- H01M2300/0017—Non-aqueous electrolytes
- H01M2300/0025—Organic electrolyte
- H01M2300/0028—Organic electrolyte characterised by the solvent
- H01M2300/0034—Fluorinated solvents
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M2300/00—Electrolytes
- H01M2300/0017—Non-aqueous electrolytes
- H01M2300/0025—Organic electrolyte
- H01M2300/0028—Organic electrolyte characterised by the solvent
- H01M2300/0037—Mixture of solvents
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- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
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Abstract
The present invention provides a kind of lithium ion secondary battery, including anode, cathode, diaphragm and nonaqueous electrolytic solution;The nonaqueous electrolytic solution includes basic components and electrolytic salt, and the basic components include solvent;The solvent includes fluorine-containing and phosphorous compound and t-carboxylic acid esters.The nonaqueous electrolytic solution can achieve the purpose that be obviously improved performance of lithium-ion secondary battery.
Description
Technical field
The present invention relates to a kind of lithium ion secondary batteries.
Background technique
In recent years, electric car is widely paid close attention to as the new energy vehicles, what lithium ion secondary battery had
The remarkable advantages such as high power density, high-energy density, long circulation life, just gradually replace conventional batteries.
However, electric car event on fire occasionally has generation, security performance is that lithium ion secondary battery expands application always
One " stumbling-block ".It is inflammable carbonic ester (ether) mixed solvent this is mainly due to commercialized electrolyte for lithium ion battery
With LiPF6Compound system, overcharge, short circuit, it is heated etc. under the conditions ofs, inside battery due to heat aggregation can cause thermal runaway into
And lead to batteries caught fire, burning, or even explosion.Carboxylic acid ester series solvent dielectric constant is higher and viscosity is smaller, is except carbonic ester
The nonaqueous electrolytic solution solvent being widely used.Previously, it is commonly used in the demanding lithium ion secondary of low temperature output characteristics
Battery.With the pursuit to high-energy density, the load quality of positive and negative anodes increases, compacted density improves, the infiltration to electrolyte
Ability is it is also proposed that requirements at the higher level.Linear carboxylate includes methyl formate, ethyl acetate, methyl butyrate, ethyl propionate and propionic acid first
The viscosity ratio carbonate solvent of ester etc., this kind of solvent is small, as the solvent of electrolyte, can be substantially reduced the viscosity of electrolyte,
Electrolyte is promoted to the wellability of pole piece, diaphragm, diffusion velocity of the lithium ion in electrode and diaphragm micro-hole is promoted, to mention
The high rate performance of high lithium secondary battery simultaneously inhibits lithium to be precipitated on cathode pole piece surface simultaneously.However, level-one carboxylate, second level carboxylic acid
Ester electrochemical window is relatively narrow, when cathode uses the carbon material such as graphite of highly crystallineization, the shape on cathode due to lithium metal or sodium
Viability species (C6Li), the reactive hydrogen on the carbon atom adjacent with carbonyl in carboxylate reacts, and generates gas, causes electricity
Pond internal resistance rises, or cycle characteristics and charged retention performance is caused to decline.In addition, linear carboxylate is molten for nonaqueous electrolytic solution
When agent, the feature low, inflammable, that oxidation resistance is not high enough of flash-point causes the battery core security risk prepared by it big.Most attach most importance to
It wants, the high wetting ability of linear carboxylate has dual character.On the one hand, as described above, be conducive to electrolyte to pole piece, every
The infiltration of film, promotes battery performance to circulate benignly;On the other hand, electrolyte also will increase the wetability of gel, cause electricity
Encapsulation difficulty between pond tab and battery outer packing (aluminum plastic film) is promoted, and is shown as the insulation resistance decline of battery, is made for a long time
Used time, there are security risks.In order to widen the electrochemical window of carboxylate, alpha-fluorocarboxylate ester is also widely studied.Present invention research
Personnel have found that alpha-fluorocarboxylate ester, such as Trifluoroacetic Acid Ethyl Ester, chemical property are still not sufficiently stable by many experiments.Pass through
Fluoro, since fluorine atom is strong electron-withdrawing group group, leads to carboxylic acid although can increase the oxidation resistance of carboxylic acid ester molecule
Carbonyl in ester molecule further polarizes, carbonylic carbon atom or the enhancing of carbonylic oxygen atom reactivity, intrinsicization of electrolyte
It learns stability decline and still not can solve the relatively low problem of the insulation resistance between battery pole ear and battery outer packing.
Summary of the invention
The present invention provides a kind of lithium ion secondary battery, including anode, cathode, diaphragm and nonaqueous electrolytic solution;It is described non-aqueous
Electrolyte includes basic components and electrolytic salt, and the basic components include solvent composition;The solvent include as formula (I) and/
Or the fluorine-containing and phosphorous compound as shown in formula (II), and the t-carboxylic acid esters as shown in formula (A):
Wherein, the R is selected from the alkyl that carbon atom number is 1~8;The R1、R2And R3It is respectively selected from least one hydrogen atom
Be replaced by fluorine atoms and carbon atom number be 1~4 alkyl or R1、R2And R3At least one hydrogen atom is respectively selected to be taken by fluorine atom
The alkoxy that generation and carbon atom number are 1~4;The X1~X6Respectively indicate the alkoxy that carbon atom number is 1~8;Or X1~X6Point
It Biao Shi not fluorine atom.
Formula (I) of the present invention and/or as formula (II) be fluorine-containing and phosphorous compound, the X1~X6Respectively indicate carbon atom
The fluorine-containing alkoxy that number is 1~8;Or X1~X6Respectively indicate fluorine atom.
The t-carboxylic acid esters of special construction are good to the wetability of PP/PE material in the present invention, and presently used ear pole material
The overwhelming majority uses PP material as gel (guaranteeing to adhere between tab and outer packing).This can cause may in gel
(infiltration) a small amount of t-carboxylic acid esters are sucked, and then cause the insulation resistance between battery pole ear and outer packing relatively low, does not meet and wants
It asks.This is because insulation resistance can reduce because of Material degradation, the organic matter of surface attachment, dust and water droplet etc..And tertiary carboxylic acid
Ester is significantly stronger than the carbonate solvent (such as dimethyl carbonate) of normal linear to the wetting action of gel, causes insulation resistance inclined
It is low.In addition, the t-carboxylic acid esters flash-point of special construction of the present invention is relatively low, causes the flash-point of electrolyte also very low, is highly combustible,
And then cause prepared battery core security risk big.In addition, the t-carboxylic acid esters of special construction are as electrolyte solvent, resistance to oxidation
Ability is high not enough, and the direction of lithium battery towards high-energy density high voltage is developed at present, and the entirety for needing to improve electrolyte is resistance to
Oxidability.The present inventor works as the fluorine-containing and phosphorous compound and the present invention of special construction of the present invention by the discovery that studies for a long period of time
The t-carboxylic acid esters compounding of special construction can solve above-mentioned technical problem.
In addition, all do not contain hydrogen atom in the present invention in the t-carboxylic acid esters of special construction on the ortho position carbon atom of carbonyl, and
There are three substituent group on the carbon of ortho position, steric hindrance is big.On the one hand this structure has prevented side reaction caused by ortho-hydrogens;On the other hand,
Three substituent groups on the carbon atom of ortho position, due to space steric effect, so that bioactive molecule can not protect function close to functional group
Group inhibits solvent to be oxidized and/or restore, improves the chemical and electrochemically stable of electrolyte to greatest extent from " attack "
Property.Therefore, three-level carboxylate is one of the fine solvent of high energy density cells nonaqueous electrolytic solution.
As an implementation, the R1、R2、R3It is respectively selected from trifluoromethyl, 2,2,2- trifluoroethyl, 1,1,1,3,
3,3- hexafluoro isopropyl, perfluoro-t-butyl, seven fluorine normal-butyl of 2,2,3,3,4,4,4-, trifluoromethoxy, 2,2,2- trifluoroethoxy
At least one in base, seven fluorine n-butoxy of 2,2,2,3,3,3- hexafluoro isopropoxy, perfluor tert .-butoxy and 2,2,3,3,4,4,4-
Kind.
By inventor study for a long period of time discovery in the nonaqueous electrolytic solution using fluorine-containing and phosphorus-containing compound and t-carboxylic acid esters as
When solvent, the anti-flammability and barotolerance of electrolyte itself are not only improved, is also improved between battery pole ear and battery outer packing
Insulation resistance.
As an implementation, the X1~X6It is respectively selected from fluorine atom, 2,2,2- trifluoro ethoxy and 2,2,2,3,3,
At least one of 3- hexafluoro isopropoxy.
As an implementation, described fluorine-containing and phosphorus-containing compound is selected from three trifluoromethyl phosphates, three (2,2,2- tri-
Fluoro ethyl) phosphate, three (1,1,1,3,3,3- hexafluoro isopropyl) phosphates, three perfluoro-t-butyl phosphates, three (2,2,3,3,
Seven fluorine normal-butyl of 4,4,4-) it is phosphate, bis trifluoromethyl phosphinic acid methyl ester, bis- (2,2,2- trifluoroethyl) phosphinicacid ethyl esters, double
(1,1,1,3,3,3- hexafluoro isopropyl) phosphinicacid ethyl ester, bis- (seven fluorine normal-butyl of 2,2,3,3,4,4,4-) phosphinicacid ethyl esters, first
Five fluorine ring triphosphine nitrile of oxygroup, five fluorine ring triphosphine nitrile of ethyoxyl, five fluorine ring triphosphine nitrile of positive propoxy, five fluorine ring triphosphine of isopropoxy
Nitrile, five fluorine ring triphosphine nitrile of n-butoxy, five fluorine ring triphosphine nitrile of isobutoxy, five fluorine ring triphosphine nitrile of tert-butoxy, (2,2,2- trifluoro
Ethyoxyl) five fluorine phosphine nitrile fluorine ring triphosphine nitriles, (2,2,2,3,3,3- hexafluoro isopropoxy) five fluorine phosphine nitrile fluorine ring triphosphine nitrile, 2,4- bis-
Methoxyl group -2,4,6,6- ptfe ring triphosphine nitrile, 2,4- diethoxy -2,4,6,6- ptfe ring triphosphine the nitrile, (2,2,2- tri- of 2,4- bis-
Fluorine ethyoxyl) -2,4,6,6- tetrafluoro phosphine nitrile fluorine ring triphosphine nitrile and 2- methoxyl group -4- ethyoxyl -2,4,6,6- ptfe ring triphosphine nitrile
At least one of.
As an implementation, the R is methyl or ethyl.
As an implementation, the t-carboxylic acid esters and fluorine-containing and phosphorus-containing compound mass ratio are 1:8~60:1;It is excellent
It is selected as 3:5~30:1.In the present invention, if t-carboxylic acid esters and fluorine-containing and phosphorus-containing compound ratio are excessively high, electrolyte profit will lead to
It is moist to make battery core defective insulation by force very much, high-temperature behavior and the high rate performance decline of electrolyte;If t-carboxylic acid esters and it is fluorine-containing and
The ratio of phosphorus-containing compound is too low, can neither preferably soak to core material, can not improve the whole high of electrolyte
Temperature stability.
As an implementation, the t-carboxylic acid esters and fluorine-containing and phosphorus-containing compound gross mass are the basic components
The 2.0%~85.0% of gross mass;Preferably 15.0%~70.0%;Further preferably 55.0%~70.0%.
As an implementation, the solvent further includes other solvents, and other solvents are selected from carbonic ester, sulfurous acid
At least one of ester, sulphonic acid ester, sulfone, ether, amide, organo-silicon compound, organoboron compound, nitrile and ionic liquid.
As an implementation, the cationic structural of the ionic liquid is selected from such as flowering structure:
R, R in above-mentioned nitrogenous compound structure1、R2、R3、R4、R5、R6Be independently selected from alkyl, alkenyl, alkynyl,
Phenyl, aryl;Or it is independently selected from having at least one of boracic, silicon, nitrogen, phosphorus, oxygen, sulphur, fluorine, chlorine, bromine and iodine element
Machine group;Described R, R1、R2、R3、R4、R5、R6It can be independent substituent group, be also possible to adjacent group joint cyclization.
As an implementation, the anion structure of the ionic liquid is selected from such as flowering structure:
As an implementation, the quality of the ionic liquid is the 0~99.5% of the gross mass of the basic components;
Preferably 0~50.0%;Further preferably 0~30.0%.
As an implementation, other solvents are selected from ethylene carbonate, fluoroethylene carbonate, polypropylene carbonate
Ester, butylene carbonate and carbonic acid Asia enester, methyl carbonic acid acrylic ester, ethyl carbonate acrylic ester, methyl carbonic acid phenol ester, carbonic acid second
Enester, halogenated ethylene carbonate, propene carbonate, butylene, dimethyl carbonate, diethyl carbonate, methyl ethyl carbonate, carbon
Sour first propyl ester, hexyl acetate, isobutyl acetate, propyl isobutyrate, two pivalate of 1,3- propylene glycol, two spy penta of 1,4- butanediol
Acid esters, ethylene sulfite, propylene sulfite, butylene sulfite, dimethyl sulfite, sulfurous acid diethyl ester, sulfolane,
Dimethyl sulfoxide, second methyl sulfoxide, 1,3- propane sulfonic acid ester, 1,4- butyl sultone, dioxolanes, dimethoxy propane, dimethyl
Dimethoxysilane, special valeronitrile, valeronitrile, 2,2- methyl pentane nitrile, bis- (trimethyl fluoride sulfonyl) imines of N- methyl-N- butyl piperidine
At least one of salt and bis- (trimethyl fluoride sulfonyl) inferior amine salts of N- Methyl-N-propyl pyrrolidines.
As an implementation, the carbonic ester includes cyclic carbonate and linear carbonate;The cyclic carbonate
Selected from least one of ethylene carbonate, fluoroethylene carbonate, propylene carbonate, butylene carbonate and carbonic acid Asia enester;Institute
It states linear carbonate and is selected from least one of dimethyl carbonate, diethyl carbonate and methyl ethyl carbonate.
As an implementation, the quality of the carbonic ester is the 0~99.5% of the gross mass of the basic components.It is excellent
It is selected as 0~50.0%.Further preferably 0~30.0%.
As an implementation, the electrolytic salt includes alkali metal salt, and the alkali metal salt includes fluorine-containing alkali gold
Belong to lithium salts and/or fluorine-containing alkali metal sodium salt;The alkali metal lithium salts is selected from LiPF6、LiBF4、LiN(SO2CF3)2、LiN
(SO2C2F5)2、LiN(SO2F)2、LiPO2F2、LiCF3SO3、LiC(SO2CF3)3、LiPF3(CF3)3、LiPF3(C2F5)3、LiPF3
(iso-C3F7)3、LiPF5(iso-C3F7)、LiB(C2O4)2、LiBF2(C2O4) and Li2B12F12At least one of;The alkali metal
Sodium salt is selected from NaPF6、NaBF4、NaN(SO2CF3)2、NaN(SO2C2F5)2、NaN(SO2F)2、NaPO2F2、NaCF3SO3、NaC
(SO2CF3)3、NaPF3(CF3)3、NaPF3(C2F5)3、NaPF3(iso-C3F7)3、NaPF5(iso-C3F7)、NaBF2(C2O4) and
Na2B12F12At least one of.
As an implementation, in the nonaqueous electrolytic solution, the concentration of the alkali metal salt be 0.5mol/L~
3.0mol/L;Preferably 0.8mol/L~1.8mol/L;Further preferably 0.9mol/L~1.5mol/L.
As an implementation, the basic components further include additive;The additive includes film for additive, prevents
At least one of overcharging additive, flame-retardant additive, conductive additive and wetting additive.
As an implementation, the film for additive includes organic film for additive and inorganic film for additive;
Organic film for additive is selected from ionic liquid, sulfuric ester, sulfite, sulfone, sulfoxide, sulphonic acid ester, carbonic ester, halogenated carbonic acid
At least one of ester, halogenated carboxylic ester, unsaturated carbon acid ester containing double bond, nitrile, crown ether and organic boride;The inorganic film forming adds
Agent is added to be selected from LiBOB, LiODBF, NaBOB, NaODBF, Li2CO3、Na2CO3、K2CO3And NH4At least one of I.
As an implementation, the anti-overcharge additive is selected from oxidationreduction to additive and electropolymerization additive.
As an implementation, the anti-overcharge additive is selected from following at least one:
As an implementation, the flame-retardant additive in non-halogenated phosphate, amide and ionic liquid at least
It is a kind of.
As an implementation, the conductive additive include cationic ligand compound, anion ligand compound,
In neutral ligand compound, amine, crown ether, cryptand compound, fluoro-alkyl boride, alkyl boron compounds and azepine ether at least
It is a kind of.
As an implementation, the wetting additive includes carbonic ester containing aryl or carbon atom quantity is 1~20
Alkyl carbonic ester and tertiary ammonium surfactant.
As an implementation, the quality of the additive is the 0~20.0% of the basic components gross mass;It is preferred that
It is 3.0%~15.0%;Further preferably 0~5.0%.
In the present invention, the lithium ion secondary battery, in addition to use heretofore described positive electrode active material,
Outside the active material of negative electrode material, diaphragm and nonaqueous electrolytic solution, it is constructed and is not construed as limiting, also not to its process for machining and manufacturing
Make specific restriction, it can be identical as common lithium-ion secondary cell.Described is the various shapes such as cylindrical type, square, outer packing
It can be metal-back and be also possible to aluminum plastic film, can design according to the actual application.
As an implementation, it is multiple to be selected from lithium nickel cobalt manganese oxide, sodium nickel cobalt manganese for the active material of the anode
Close oxide, sodium nickel/cobalt composite oxide, lithium nickel cobalt aluminium composite oxide, li-mn-ni compound oxide, olivine-type lithium iron phosphorus
At least one of oxide, lithium and cobalt oxides, sodium cobalt/cobalt oxide, lithium manganese oxide and sodium manganese oxide.
In the present invention, the lithium ion secondary battery anode can be manufactured with method as described below.
Firstly, mixing powdery positive active material, conductive agent and bonding agent, and solvent is added, slurry is made.Anode slurry
The mixing ratio of each material in material often determines the chemical property of lithium ion secondary battery.Generally, each solid in anode sizing agent
The gross mass of material composition is similar with the anode of common lithium ion secondary battery as 100 mass parts, preferably by active anode compartment
Material content is set as 80~95 mass parts, conductive material content is set as 2~15 mass parts, bonding agent content be set as 1~
18 mass parts.
Anode sizing agent obtained is coated on to the surface of aluminium foil collector, and is dried so that solvent volatilizees.Root
According to needs, can also be pressurizeed by roll-in method etc., to improve electrode density.Sheet-like anode can be manufactured as a result,.It can be according to mesh
Battery is marked, sheet-like anode is cut with size appropriate.Anode manufacturing method be not limited to illustrated by method, can also adopt
With other methods.When manufacturing anode pole piece, as conductive agent, such as carbon can be used, can be amorphous carbon and be also possible to
Crystalline carbon, including it is charcoal, coke, bone black, sugar charcoal, active carbon, carbon black, coke, graphitized intermediate-phase carbosphere (MCMB), soft
Carbon, hard carbon and graphite etc.;Divide from microstructure, the carbon can be carbon nanotube, graphite flake, fullerene, graphite
Alkene etc.;Divide from microscopic appearance, the carbon can be carbon fiber, carbon pipe, carbon ball etc..It is preferred that highly electron conductive, structure
The good carbon material of intensity.
Bonding agent plays a part of for positive active material particle to be connected and fixed, including hydrophilic polymer, that is, carboxymethyl cellulose
Element (CMC), methylcellulose (MC), cellulose acetate-phthalate (CAP), HYDROXY PROPYL METHYLCELLULOSE (HPMC), hydroxyl
Propyl methocel phthalic acid ester (HPMCP), polyvinyl alcohol (PVA), polyethylene glycol oxide (PEO) etc. and hydrophobicity are poly-
Close object material such as polytetrafluoroethylene (PTFE) (PTFE), tetrafluoroethene perfluoroalkyl vinyl ether copolymer (FEP), Kynoar
(PVDF), the fluorine resins such as polyethylene-TFE copolymer (ETFE) and acetate ethylene copolymer, styrene-butadiene
At least one in rubbers such as block copolymer (SBR), acrylic acid modified SBR resin (SBR system latex), acacia gum etc.
Kind.Wherein, it is preferable to use the fluorine resins such as PTFE, PVDF.Electronic polymer, which is led, as binder has obviously advantage,
It is the developing direction for the binder in electrochemical device.
It is made an addition in solvent appropriate, and made by positive electrode active materials and foregoing illustrative conductive agent and bonding agent etc.
It disperses or dissolves and is mixed, and slurry is thus made.
The slurry modulated is coated on plus plate current-collecting body, and after making solvent volatile dry, carries out roll-in.As representative
The example of property, can be used apparatus for coating (coating machine), with defined thickness in collection liquid surface coating sizing-agent.Simultaneously to coating thickness
There is no particular limitation, can suitably be set according to the shape or purposes of Anode and battery.It is dry to remove solvent after coating,
The positive electrode active material layer of specific thickness is formed in collection liquid surface, roller process is then carried out as needed, it is thick to obtain target
The anode pole piece of degree.
As an implementation, the active material of the cathode is selected from graphite, carbonaceous mesophase spherules, agraphitic carbon, lithium
At least one of titanium oxygen compound, lithium oxyvanadium compound, silica-base material, tin-based material and transition metal oxide;The graphite
Including artificial graphite and natural graphite;The agraphitic carbon includes hard carbon and soft carbon.
In the present invention, the cathode pole piece is by the active material and conductive agent, adhesive, solvent by certain
Ratio is evenly applied on copper foil after being mixed and made into slurry, then is made through dry and rolling.
The description of the above-mentioned manufacture to battery pole piece be based on current conventional mass production process, but be not precluded with
It is expected to the manufacture that plasma spraying technology, 3D printing technique for realizing etc. are applied to lithium ion secondary battery pole piece afterwards.
As an implementation, the diaphragm is selected from polyolefin fusion drawn diaphragm;Or the diaphragm is selected from PET and (gathers
Ethylene glycol terephthalate), Kynoar, the diaphragm that at least one of aramid fiber and polyamide are substrate;Or selected from high soft
Change the diaphragm that polyolefin is coated on point porous matrix material.
As an implementation, the polyolefins fusion drawn diaphragm is polypropylene single-layer septum or polyethylene single layer
Diaphragm;Or three layers of composite diaphragm of polypropylene, polyethylene/polypropylene.
As an implementation, the porous matrix material of the high softening-point refers to that softening point is porous higher than 150 DEG C
Basis material.
In the present invention, diaphragm is one of key components of battery, between the positive and negative electrode of battery, be used to every
From positive and negative electrode, internal short-circuit of battery is avoided, while guaranteeing that ion can be passed through in charge and discharge again.For battery
Diaphragm is a kind of electronic insulating film of porous structure, has high ionic conduction performance and good mechanical strength, Neng Gou
It is stabilized, is not chemically reacted for a long time in electrolyte.In the secondary battery, the superiority and inferiority of membrane properties directly affects battery
Internal resistance, capacity, charging and discharging currents density, cycle life and safety etc. key performances.
The present invention provides a kind of lithium ion secondary battery and containing t-carboxylic acid esters and fluorine-containing and phosphorus-containing compound compound system
Nonaqueous electrolytic solution, not only increase the security performance of battery core, the energy density of electrolyte, it is often more important that improve battery core
The capacity retention ratio of high temperature circulation.
The above description is only an overview of the technical scheme of the present invention, in order to better understand the technical means of the present invention,
And it can be implemented in accordance with the contents of the specification, and in order to allow above and other objects, features and advantages of the invention can
It is clearer and more comprehensible, it is special below to lift preferred embodiment, and cooperate attached drawing, detailed description are as follows.
Detailed description of the invention
Fig. 1 is the charging and discharging curve figure of the embodiment of the present invention 1, comparative example 1, comparative example 2 and comparative example 3;
Fig. 2 is the capacity circulating curve graph of the embodiment of the present invention 1, comparative example 1, comparative example 2 and comparative example 3;
Fig. 3 is the capacity retention ratio cyclic curve figure of the embodiment of the present invention 1, comparative example 1, comparative example 2 and comparative example 3.
Specific embodiment
The present invention is described in detail in specific embodiment below, and then the present invention is not restricted to following implementation
Example.
The present invention is not construed as limiting lithium ion secondary battery structure, can be cylindrical type, square or coin shape, flexible package or
Steel shell or aluminum hull.Using stacking aluminum plastic film flexible-packed battery in the embodiment of the present invention, design capacity 15Ah, diaphragm is using polyolefin
Class fusion drawn diaphragm.In addition, also having using 2025 type button cells.
When using stacking aluminum plastic film flexible-packed battery, the positive electrode of 15Ah secondary cell uses LiNi0.5Co0.2Mn0.3O2
(NCM523), cobalt acid lithium LiCoO2Or LiMn2O4 LiMn2O4;Negative electrode material uses substance cited in each embodiment.As leading
Electric agent can be used carbon, such as can be amorphous carbon and be also possible to crystalline state carbon, including charcoal, coke, bone black, sugar charcoal, activity
Charcoal, carbon black, coke, graphitized intermediate-phase carbon microballon (MCMB), soft carbon, hard carbon and graphite etc.;Divide from microstructure, institute
The carbon stated can be carbon nanotube, graphite flake, fullerene, graphene etc.;Divide from microscopic appearance, the carbon can be
Carbon fiber, carbon pipe, carbon ball etc..One of graphene, VGCF, acetylene black and KS-6 or more are used in the embodiment of the present invention
Kind.Binder will play electrode active material particle and be connected and fixed, including hydrophilic polymer such as carboxymethyl cellulose
(CMC), methylcellulose (MC), cellulose acetate-phthalate (CAP), HYDROXY PROPYL METHYLCELLULOSE (HPMC), hydroxypropyl
Ylmethyl cellulose phthalate (HPMCP), polyvinyl alcohol (PVA) and polyethylene glycol oxide (PEO) etc. or hydrophobic polymerizable
Object material such as polytetrafluoroethylene (PTFE) (PTFE), tetrafluoroethene perfluoroalkyl vinyl ether copolymer (FEP), Kynoar (PVDF),
The fluorine resins such as polyethylene-TFE copolymer (ETFE) and acetate ethylene copolymer, Styrene-Butadiene block copolymerization
The rubbers such as object (SBR), acrylic acid modified SBR resin (SBR system latex), acacia gum.It is used in the embodiment of the present invention
PVDF。
When evaluating material and electrolyte property using button cell, by negative electrode material, conductive agent acetylene black and binder
Kynoar (PVDF) in mass ratio 80:10:10 mixing, and solvent N-methyl pyrilidone is added, slurry is made.By slurry
Coated on the aluminium foil or copper foil with a thickness of 20 μm, then it is dried in vacuo at 120 DEG C, strikes out the circle that diameter is about 14mm
Electrode is made in piece.Use metal lithium sheet as to electrode.Diaphragm is porous polyethylene membrane, 20 μm of thickness, in the hand of Ar gas shielded
2025 type button cells are assembled into casing.
The formula composition of the embodiment of the present invention 1~15 and comparative example 1~10 is shown in Table 1;1~15 He of the embodiment of the present invention
The physical function parameter test result of comparative example 1~10 is shown in Table 2;The electricity of the embodiment of the present invention 1~15 and comparative example 1~10
Pond performance parameter test the results are shown in Table shown in 3.
The present invention to embodiment 1, comparative example 1, comparative example 2 and comparative example 3 carry out charge and discharge, capacity and capacity retention ratio into
Row test, test result as shown in Figure 1, Figure 2 and Figure 3.
Embodiment 1
Electrolyte quota
By pivalic acid methyl esters and three (2,2,2- trifluoroethyl) phosphates with mass ratio for 2:1 is configured without aqueous solvent mixing
Object, on the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 72.0wt.%;It is added ethylene carbonate (EC),
On the basis of the basic components of nonaqueous electrolytic solution, content 26.0wt.%;It is added additive vinylene carbonate (VC), with non-
On the basis of the basic components of water electrolysis liquid, content 2.0wt.%;It is slowly added to electrolytic salt LiPF6And cooled down, it is formed
Nonaqueous electrolytic solution, the electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 24.7 DEG C in embodiment 1.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 51 ° to the contact angle of gel.
Battery production:Aluminum plastic film flexible-packed battery is laminated in 15Ah, and positive electrode uses LiNi0.5Co0.2Mn0.3O2
(NCM523), negative electrode material uses hard carbon.
Battery performance test:By above-mentioned flexible-packed battery when room temperature 1C discharges, energy density about 168.0Wh/kg.Battery core
Insulation resistance be 9566 megaohms.Above-mentioned flexible-packed battery is filled in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Electric discharge, i.e. constant current (rate of charge 3C) charge to 4.3V, and then constant current (discharge-rate 3C) is discharged to 2.5V.The effect of charge and discharge
Rate is basically stable at 100% or so.First week discharge capacity can achieve 14.1Ah, and recycling 50 weeks discharge capacities is 11.8Ah, hold
Measure conservation rate 83.7%.Energy density can achieve 167.9Wh/kg to battery core for the first time under the test condition, and circulation can reach for 50 weeks
To 125.8Wh/kg.
Embodiment 2
Electrolyte quota
By pivalic acid ethyl ester and five fluorine ring triphosphine nitrile of ethyoxyl with mass ratio for 2:1 is configured without aqueous solvent mixture, with
On the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 36.0wt.%.EC is added, with the base of nonaqueous electrolytic solution
On the basis of plinth component, content 26.0wt.%.It is added methyl ethyl carbonate (EMC), using the basic components of nonaqueous electrolytic solution as base
Standard, content 36.0wt.%.Additive VC, on the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.% is added.
It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6In the nonaqueous electrolytic solution
In concentration be 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 34.2 DEG C in embodiment 2.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 53 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 173.0Wh/kg reaches energy density ratings.Battery core
Insulation resistance be 15380 megaohms.Under 60 DEG C of environment temperatures by above-mentioned flexible-packed battery in 2.5~4.3V voltage range
3C3D charge and discharge.The efficiency of charge and discharge is basically stable at 100% or so.First week discharge capacity can achieve 14.3Ah, circulation 50
All discharge capacities are 14.1Ah, capacity retention ratio 98.6%.Energy density can achieve battery core for the first time under the test condition
155.3Wh/kg, circulation can achieve 153.7Wh/kg in 50 weeks.
The result of embodiment 2 is again demonstrated can be significantly improved using high-temperature behavior after t-carboxylic acid esters, and control tertiary carboxylic acid
It can control the insulation resistance of battery core while ester content using fluorine-containing and phosphorous five fluorine ring triphosphine nitrile of compound ethyoxyl.It is real
The insulation resistance for applying example 2 is higher than embodiment 1.
Embodiment 3
Electrolyte quota
By pivalic acid ethyl ester and three (2,2,2- trifluoroethyl) phosphates with mass ratio for 1:8 are configured without aqueous solvent mixing
Object, on the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 45.0wt.%.EC and dimethyl carbonate is added
(DMC), on the basis of the basic components of nonaqueous electrolytic solution, content is followed successively by 26.0wt.% and 27.0wt.%.Additive is added
VC, on the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.%.It is slowly added to electrolytic salt LiPF6And it is subject to cold
But, nonaqueous electrolytic solution, the electrolytic salt LiPF are formed6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 26.2 DEG C in embodiment 3.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 59.5 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 161.0Wh/kg is close to reach energy density ratings.
The insulation resistance of battery core is 45900 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 13.2Ah, and energy density is 136.6Wh/kg for the first time.Capacity is after having recycled 35 weeks
9.8Ah, capacity retention ratio 74.2%, energy density 99.9Wh/kg.
Embodiment 4
Electrolyte quota
By pivalic acid ethyl ester and three (1,1,1,3,3,3- hexafluoro isopropyl) phosphates with mass ratio for 16:1 is configured without
Aqueous solvent mixture, on the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 45.0wt.%.Be added EC and
DMC, on the basis of the basic components of nonaqueous electrolytic solution, content is followed successively by 26.0wt.% and 27.0wt.%.Additive VC is added,
On the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down,
Form nonaqueous electrolytic solution, the electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 23.0 DEG C in embodiment 4.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 46.5 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 145.4Wh/kg is close to reach energy density ratings.
The insulation resistance of battery core is 2185 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 10.9Ah, and energy density is 116.6Wh/kg for the first time.Capacity is after having recycled 35 weeks
10.3Ah, capacity retention ratio 94.4%, energy density 109.9Wh/kg.
Embodiment 5
Electrolyte quota
By pivalic acid ethyl ester and three (2,2,2- trifluoroethyl) phosphates with mass ratio for 1:1 is configured without aqueous solvent mixing
Object, on the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 2.0wt.%.EC and diethyl carbonate is added
(DEC), on the basis of the basic components of nonaqueous electrolytic solution, content is followed successively by 26.0wt.% and 70.0wt.%.Additive is added
VC, on the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.%.It is slowly added to electrolytic salt LiPF6And it is subject to cold
But, nonaqueous electrolytic solution, the electrolytic salt LiPF are formed6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 33.2 DEG C in embodiment 5.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 55.0 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 168.7Wh/kg basically reaches energy density ratings.
The insulation resistance of battery core is 36570 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 14.1Ah, and energy density is 154.9Wh/kg for the first time.Capacity is after having recycled 35 weeks
13.7Ah, capacity retention ratio 97.1%, energy density 150.4Wh/kg.
Embodiment 6
Electrolyte quota
By pivalic acid ethyl ester and three (2,2,2- trifluoroethyl) phosphates with mass ratio for 10:7, which are configured without aqueous solvent, mixes
Object is closed, on the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 85.0wt.%.EC is added, with non-aqueous solution electrolysis
On the basis of the basic components of liquid, content 13.0wt.%.Additive VC is added, on the basis of the basic components of nonaqueous electrolytic solution,
Content is 2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt
LiPF6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 25.6 DEG C in embodiment 6.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 52.0 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 167.8Wh/kg basically reaches energy density ratings.
The insulation resistance of battery core is 13115 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 13.5Ah, and energy density is 142.3Wh/kg for the first time.Capacity is after having recycled 35 weeks
13.1Ah, capacity retention ratio 97.0%, energy density 137.4Wh/kg.
Embodiment 7
Electrolyte quota
By pivalic acid ethyl ester and five fluorine ring triphosphine nitrile of ethyoxyl with mass ratio for 25:3 are configured without aqueous solvent mixture, with
On the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 28.0wt.%.EC is added, with the base of nonaqueous electrolytic solution
On the basis of plinth component, content 30.0wt.%.EMC is added, on the basis of the basic components of nonaqueous electrolytic solution, content is
40.0wt.%.Additive 1 is added:VC, on the basis of the basic components of nonaqueous electrolytic solution, content 1.5wt.%.Addition is added
Agent 2:Difluorophosphate (LiPO2F2), on the basis of the basic components of nonaqueous electrolytic solution, content 0.5wt.%.It is slowly added to electricity
Solve matter salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is
1.0mol/L。
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 26.3 DEG C in embodiment 7.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 51.0 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 165.4Wh/kg is close to reach energy density ratings.
The insulation resistance of battery core is 9020 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 14.0Ah, and energy density is 151.3Wh/kg for the first time.Capacity is after having recycled 35 weeks
13.7Ah, capacity retention ratio 97.8%, energy density 148.2Wh/kg.
Embodiment 8
Electrolyte quota
By t-carboxylic acid esters mixture and fluorine-containing and phosphorus-containing compound mixture with mass ratio for 20:13 are configured without aqueous solvent
Mixture, on the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 66.0wt.%.Wherein, t-carboxylic acid esters are mixed
Close object composition be pivalic acid methyl esters and pivalic acid ethyl ester with mass ratio for 1:1 mixing.Wherein, fluorine-containing and phosphorus-containing compound mixes
The composition of object is five fluorine ring triphosphine nitrile of ethyoxyl and three (2,2,2- trifluoroethyl) phosphates with mass ratio for 1:1 mixing.It is added
EC, on the basis of the basic components of nonaqueous electrolytic solution, content 32.0wt.%.Additive VC is added, with the base of nonaqueous electrolytic solution
On the basis of plinth component, content 2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, institute
State electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 44.0 DEG C in embodiment 8.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 50.5 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 160.6Wh/kg is close to reach energy density ratings.
The insulation resistance of battery core is 8390 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 14.1Ah, and energy density is 151.7Wh/kg for the first time.Capacity is after having recycled 35 weeks
14.1Ah, capacity retention ratio 100.0%, energy density 151.2Wh/kg.
Embodiment 9
Electrolyte quota
By pivalic acid ethyl ester and 2- methoxyl group -4- ethyoxyl ptfe ring triphosphine nitrile with mass ratio for 1:1 be configured without it is water-soluble
Agent composition, on the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 20.0wt.%.EC is added, with non-aqueous
On the basis of the basic components of electrolyte, content 25.0wt.%.EMC is added, on the basis of the basic components of nonaqueous electrolytic solution,
Content is 53.0wt.%.Additive VC, on the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.% is added.Slowly
Electrolytic salt LiPF is added6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6In the nonaqueous electrolytic solution
Concentration is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 37.0 DEG C in embodiment 9.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 60.0 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 161.2Wh/kg basically reaches energy density ratings.
The insulation resistance of battery core is 44850 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 14.0Ah, and energy density is 151.8Wh/kg for the first time.Capacity is after having recycled 35 weeks
13.9Ah, capacity retention ratio 99.2%, energy density 150.7Wh/kg.
Embodiment 10
Electrolyte quota
By pivalic acid methyl esters and three perfluoro-t-butyl phosphates with mass ratio for 3:1 is configured without aqueous solvent mixture, with
On the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 40.0wt.%.EC is added, with the base of nonaqueous electrolytic solution
On the basis of plinth component, content 25.0wt.%.EMC is added, on the basis of the basic components of nonaqueous electrolytic solution, content is
33.0wt.%.Additive VC, on the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.% is added.It is slowly added to electricity
Solve matter salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is
1.0mol/L。
Electrolyte flash-point is 27.8 DEG C.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 52.5 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 158.8Wh/kg is close to reach energy density ratings.
The insulation resistance of battery core is 14630 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 13.0Ah, and energy density is 133.2Wh/kg for the first time.Capacity is after having recycled 35 weeks
12.3Ah, capacity retention ratio 94.6%, energy density 121.8Wh/kg.
Embodiment 11
Electrolyte quota
By pivalic acid methyl esters and bis- (2,2,2- trifluoroethyl) phosphinicacid ethyl esters with mass ratio for 4:1 is configured without aqueous solvent
Mixture, on the basis of the basic components (component in addition to lithium salts) of nonaqueous electrolytic solution, the content of the mixture is
60.0wt.%.EC, on the basis of the basic components of nonaqueous electrolytic solution, content 26.0wt.% is added.EMC is added, with non-aqueous
On the basis of the basic components of electrolyte, content 12.0wt.%.Additive VC is added, is with the basic components of nonaqueous electrolytic solution
Benchmark, content 2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolyte
Salt LiPF6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte flash-point is 23.4 DEG C.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 50.0 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 148.1Wh/kg is close to reach energy density ratings.
The insulation resistance of battery core is 7655 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 12.2Ah, and energy density is 125.7Wh/kg for the first time.Capacity is after having recycled 35 weeks
10.8Ah, capacity retention ratio 88.9%, energy density 111.7Wh/kg.
Embodiment 12
Electrolyte quota
By pivalic acid methyl esters and three (2,2,2- trifluoroethyl) phosphates with mass ratio for 3:5 are configured without aqueous solvent mixing
Object, on the basis of the basic components (component in addition to lithium salts) of nonaqueous electrolytic solution, the content of the mixture is 32.0wt.%.Add
Enter EC, on the basis of the basic components of nonaqueous electrolytic solution, content 25.0wt.%.EMC is added, with the basis of nonaqueous electrolytic solution
On the basis of component, content 41.0wt.%.Additive VC is added, on the basis of the basic components of nonaqueous electrolytic solution, content is
2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6At this
Concentration in nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte flash-point is 32.5 DEG C.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 57.0 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 163.3Wh/kg is close to reach energy density ratings.
The insulation resistance of battery core is 38505 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 13.8Ah, and energy density is 148.6Wh/kg for the first time.Capacity is after having recycled 35 weeks
13.3Ah, capacity retention ratio 96.4%, energy density 144.9Wh/kg.
Embodiment 13
Electrolyte quota
It is with mass ratio with 2,4- bis- (2,2,2- trifluoroethyl) -2,4,6,6- ptfe ring triphosphine nitrile by pivalic acid methyl esters
30:1 is configured without aqueous solvent mixture, on the basis of the basic components (component in addition to lithium salts) of nonaqueous electrolytic solution, the mixing
The content of object is 15.5wt.%.EC, on the basis of the basic components of nonaqueous electrolytic solution, content 25.0wt.% is added.It is added
DEC, on the basis of the basic components of nonaqueous electrolytic solution, content 57.5wt.%.Additive VC is added, with nonaqueous electrolytic solution
On the basis of basic components, content 2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down, nonaqueous electrolytic solution is formed,
The electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte flash-point is 24.6 DEG C.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 49.5 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 162.8Wh/kg is close to reach energy density ratings.
The insulation resistance of battery core is 6880 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 14.0Ah, and energy density is 152.2Wh/kg for the first time.Capacity is after having recycled 35 weeks
13.8Ah, capacity retention ratio 98.6%, energy density 150.1Wh/kg.
Embodiment 14
Electrolyte quota
By pivalic acid methyl esters and (2,2,2- the trifluoroethyl) -2,4,6,6- ptfe ring triphosphine nitrile of 2,4- bis- with mass ratio for 4:
1 is configured without aqueous solvent mixture, on the basis of the basic components (component in addition to lithium salts) of nonaqueous electrolytic solution, the mixture
Content is 10wt.%.EC, on the basis of the basic components of nonaqueous electrolytic solution, content 25.0wt.% is added.DEC is added, with
On the basis of the basic components of nonaqueous electrolytic solution, content 63.0wt.%.Additive VC is added, with the base set of nonaqueous electrolytic solution
It is divided into benchmark, content 2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electricity
Solve matter salt LiPF6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte flash-point is 30.0 DEG C.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 54.5 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 164.1Wh/kg basically reaches energy density ratings.
The insulation resistance of battery core is 31925 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 13.7Ah, and energy density is 150.5Wh/kg for the first time.Capacity is after having recycled 35 weeks
13.4Ah, capacity retention ratio 97.8%, energy density 144.4Wh/kg.
Embodiment 15
Electrolyte quota
By pivalic acid methyl esters and five fluorine ring triphosphine nitrile of ethyoxyl with mass ratio for 60:1 is configured without aqueous solvent mixture, with
On the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 30.5wt.%.EC is added, with the base of nonaqueous electrolytic solution
On the basis of plinth component, content 25.0wt.%.DEC is added, on the basis of the basic components of nonaqueous electrolytic solution, content is
42.5wt.%.Additive VC, on the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.% is added.It is slowly added to electricity
Solve matter salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is
1.0mol/L。
Electrolyte flash-point is 22.8 DEG C.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 58.0 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 162.9Wh/kg basically reaches energy density ratings.
The insulation resistance of battery core is 5375 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 13.8Ah, and energy density is 149.3Wh/kg for the first time.Capacity is after having recycled 35 weeks
13.5Ah, capacity retention ratio 98.0%, energy density 141.7Wh/kg.
Comparative example 1
Electrolyte quota
By dimethyl carbonate (DMC) and methyl ethyl carbonate with mass ratio for 2.0:1 is configured to non-water mixed solvent, with non-aqueous
On the basis of the basic components of electrolyte, the content of the mixture is 72.0wt.%;EC is added, with the base set of nonaqueous electrolytic solution
It is divided into benchmark, content 26.0wt.%.Additive VC is added, on the basis of the basic components of nonaqueous electrolytic solution, content is
2.0wt.%;It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6At this
Concentration in nonaqueous electrolytic solution is 1.0mol/L.
Electrolysis is tested by the full-automatic silent flash point tester of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Liquid flash-point, the flash-point of basic components is 22.0 DEG C in comparative example 1.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 59 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 168.6Wh/kg, close to energy density ratings, battery core
Insulation resistance be 40930 megaohms, under 60 DEG C of environment temperatures by above-mentioned flexible-packed battery in 2.5~4.3V voltage range
3C3D charge and discharge, the efficiency of charge and discharge are basically stable at 100% or so, and first week discharge capacity can achieve 14.3Ah, circulation 50
All discharge capacities are 8.8Ah, capacity retention ratio 61.6%.Energy density can achieve battery core for the first time under the test condition
154.5Wh/kg, circulation can achieve 90.3Wh/kg in 50 weeks.
By comparing embodiment 1 and comparative example 1, it can be found that electrolyte can be improved using compounded formula of the invention
Flash-point improves the security performance of battery core, improves the energy density of electrolyte, it is often more important that the high temperature for improving battery core follows
The capacity retention ratio of ring, two embodiments are similarly circulation 50 weeks, and the conservation rate of embodiment 1 is higher by nearly 20% than comparative example 1.
Comparative example 2
Electrolyte quota
Pivalic acid methyl esters anhydrous solvent is configured, on the basis of the basic components of nonaqueous electrolytic solution, the content of the solvent is
72.0wt.%.EC, on the basis of the basic components of nonaqueous electrolytic solution, content 26.0wt.% is added.Additive VC is added, with
On the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.%.It is slowly added to electrolytic salt LiPF6And it is cooled down, shape
At nonaqueous electrolytic solution, the electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 15 DEG C in comparative example 2.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 39 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 173.6Wh/kg reaches energy density ratings.Battery core
Insulation resistance be 63 megaohms.Under 60 DEG C of environment temperatures by above-mentioned flexible-packed battery in 2.5~4.3V voltage range 3C3D
Charge and discharge.The efficiency of charge and discharge is basically stable at 100% or so.First week discharge capacity can achieve 14.4Ah, and circulation is put for 50 weeks
Capacitance is 12.2Ah, capacity retention ratio 84.7%.Energy density can achieve 159.1Wh/ to battery core for the first time under the test condition
Kg, circulation can achieve 131.5Wh/kg in 50 weeks.
By comparing embodiment 1 and comparative example 2, pivalic acid methyl esters is used alone without compounding fluorine-containing and phosphorus-containing compound
The flash-point that (comparative example 2) does not only result in electrolyte is relatively low, seriously affects the security performance of battery core, and insulation resistance is seriously inclined
It is low, or even close to minimum requirements.This it is relatively low to the contact angle of gel from 2 electrolyte basic components of comparative example it can also be seen that.And
And the high-temperature stability of 2 battery core of comparative example, it is not so good as general electrolytic liquid (comparative example 1) instead especially under the work of high voltage.
Illustrate be used alone t-carboxylic acid esters may be it is unworkable, need to compound with fluorine-containing and phosphorus-containing compound.
Comparative example 3
Electrolyte quota
Three (2,2,2- trifluoroethyl) phosphate anhydrous solvents are configured, it, should on the basis of the basic components of nonaqueous electrolytic solution
The content of solvent is 72.0wt.%.EC, on the basis of the basic components of nonaqueous electrolytic solution, content 26.0wt.% is added.Add
Enter additive VC, on the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.%.It is slowly added to electrolytic salt LiPF6
And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 120.0 DEG C of > in comparative example 3.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 62 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 139.2Wh/kg is far below energy density ratings.Electricity
The insulation resistance of core is 56250 megaohms.Under 60 DEG C of environment temperatures by above-mentioned flexible-packed battery in 2.5~4.3V voltage range
3C3D charge and discharge.Only 7.7Ah, 50 weeks discharge capacities of circulation are 3.6Ah, capacity retention ratio 46.8% to first week discharge capacity.The survey
Battery core energy density only 70.1Wh/kg for the first time under the conditions of examination, the only 30.4Wh/kg of circulation 50 weeks.
By comparing embodiment 1 and comparative example 3, three (2,2,2- trifluoroethyl) phosphates are used alone and do not compound three-level carboxylic
Acid esters (comparative example 3) directly results in battery core cannot normally play rated capacity completely, and energy density is very low.Battery core is recycled at 60 DEG C
Under stability it is also excessively poor.Illustrate to be used alone fluorine-containing and phosphorus-containing compound be it is unworkable, need t-carboxylic acid esters multiple therewith
Match.
Comparative example 4
Electrolyte quota
Prepare five fluorine ring triphosphine nitrile anhydrous solvent of ethyoxyl, on the basis of the basic components of nonaqueous electrolytic solution, the solvent
Content is 72.0wt.%.EC, on the basis of the basic components of nonaqueous electrolytic solution, content 26.0wt.% is added.Addition is added
Agent VC, on the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.%.It is slowly added to electrolytic salt LiPF6And it is subject to
It is cooling, form nonaqueous electrolytic solution, the electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
There is the phenomenon that solution layering is largely precipitated with solid quickly in electrolyte prepared by comparative example 4.This illustrates ethyoxyl
A large amount of use of five fluorine ring triphosphine nitriles cannot function as qualified electrolyte in other words with its electrolyte as main component, it is impossible to be used in
Battery core preparation.Mean that five fluorine ring triphosphine nitrile of ethyoxyl needs to compound as fluorine-containing and phosphorous compound.
Comparative example 5
Electrolyte quota
By ethyl acetate and three (2,2,2- trifluoroethyl) phosphates with mass ratio for 2:1 is configured without aqueous solvent mixing
Object, on the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 72.0wt.%.EC is added, with nonaqueous electrolytic solution
Basic components on the basis of, content 26.0wt.%.Additive VC is added to contain on the basis of the basic components of nonaqueous electrolytic solution
Amount is 2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6
Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 24.7 DEG C in comparative example 5.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 50.5 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, capacity 11.5Ah, energy density about 130.7Wh/kg cannot reach
Energy density ratings.The insulation resistance of battery core is 8860 megaohms.Under 60 DEG C of environment temperatures by above-mentioned flexible-packed battery 2.5~
3C3D charge and discharge in 4.3V voltage range.First week discharge capacity only 0.96Ah, for the first time energy density only 9.1Wh/kg.Its effect phase
When can hardly normal charge and discharge at 3C3D in battery core.
It is still (fluorine-containing and phosphorous using three (2,2,2- trifluoroethyl) phosphates by comparing embodiment 1 and comparative example 5
Compound), but what is compounded therewith is not t-carboxylic acid esters but ethyl acetate, and the capacity of battery core plays and energy density below makes
Use t-carboxylic acid esters.And under high temperature high magnification, using ethyl acetate it cannot be guaranteed that the normal charge and discharge of battery core.
Comparative example 6
Electrolyte quota
By pivalic acid methyl esters and phosphate triethyl with mass ratio for 2:1 is configured without aqueous solvent mixture, with non-water power
On the basis of the basic components for solving liquid, the content of the mixture is 72.0wt.%.EC is added, with the basic components of nonaqueous electrolytic solution
On the basis of, content 26.0wt.%.Additive VC is added, on the basis of the basic components of nonaqueous electrolytic solution, content is
2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6At this
Concentration in nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte is tested by the full-automatic close flash point instrument of Fu Lande of model FDT-0231 (referring to national standard GB/T261)
Flash-point, the flash-point of basic components is 22.3 DEG C in comparative example 1.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 45.0 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, capacity 15.1Ah, energy density about 169.1Wh/kg, close to specified
Energy density.The insulation resistance of battery core is 1562 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V under 60 DEG C of environment temperatures
3C3D charge and discharge in voltage range.First week discharge capacity is 13.2Ah, and energy density is 143.1Wh/kg for the first time.
By comparing embodiment 1 and comparative example 6, under formula rate unanimous circumstances, using pivalic acid methyl esters, but therewith
The instead of not fluorine-containing and phosphorus-containing compound of compounding, phosphorous but not fluorine-containing compound (triethyl phosphate).Comparative example 6 is to tab
Contact angle it is obviously smaller than embodiment 1, it is meant that stronger wetting ability, also imply battery core insulation resistance it is relatively low.It is true
On, the battery core insulation resistance of comparative example 6 is really obviously smaller than embodiment 1.In addition to this, 6 battery core of comparative example capacity play and
Energy density is also all lower than embodiment 1.
Comparative example 7
Electrolyte quota
By pivalic acid methyl esters and three (2,2,2- trifluoroethyl) phosphates with mass ratio for 6:5 are configured without aqueous solvent mixing
Object, on the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 88wt.%.EC is added, with nonaqueous electrolytic solution
On the basis of basic components, content 10.0wt.%.Additive VC, on the basis of the basic components of nonaqueous electrolytic solution, content is added
For 2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6?
Concentration in the nonaqueous electrolytic solution is 1.0mol/L.
Electrolyte flash-point is 26.0 DEG C.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 49.5 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 161.4Wh/kg cannot reach energy density ratings.
The insulation resistance of battery core is 5005 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 12.8Ah, and energy density is 136.7Wh/kg for the first time.Capacity is after having recycled 35 weeks
11.4Ah, capacity retention ratio 89.1%, energy density 120.0Wh/kg.
Comparative example 8
Electrolyte quota
By pivalic acid ethyl ester and five fluorine ring triphosphine nitrile of ethyoxyl with mass ratio for 6:5 are configured without aqueous solvent mixture, with
On the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 88wt.%.EC is added, with the basis of nonaqueous electrolytic solution
On the basis of component, content 10.0wt.%.Additive VC is added, on the basis of the basic components of nonaqueous electrolytic solution, content is
2.0wt.%.It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6At this
Concentration in nonaqueous electrolytic solution is 1.0mol/L.It was found that the electrolyte lithium salts is difficult to dissolve, there is solid particle.After standing 24 hours
The solid of precipitation is more.Therefore without preparation battery core.
By comparative example 7 and 8, it can be found that the solvent mixture mass fraction of compounding is likely to occur lithium salts when being greater than 85%
It cannot dissolve, battery core poor circulation, the problems such as specified energy density and capacity cannot be played.
Comparative example 9
Electrolyte quota
By pivalic acid ethyl ester and five fluorine ring triphosphine nitrile of ethyoxyl with mass ratio for 1:10 are configured without aqueous solvent mixture, with
On the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 22wt.%.EC is added, with the basis of nonaqueous electrolytic solution
On the basis of component, content 25.0wt.%.Additive EMC is added, on the basis of the basic components of nonaqueous electrolytic solution, content is
51.0wt.%.Additive VC, on the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.% is added.It is slowly added to electricity
Solve matter salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6Concentration in the nonaqueous electrolytic solution is
1.0mol/L。
Electrolyte flash-point is 25.2 DEG C.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 61.0 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 156.6Wh/kg is close to reach energy density ratings.
The insulation resistance of battery core is 55735 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 13.1Ah, and energy density is 129.4Wh/kg for the first time.Capacity is after having recycled 35 weeks
9.4Ah, capacity retention ratio 71.7%, energy density 90.1Wh/kg.
It can be found that when t-carboxylic acid esters and fluorine-containing and phosphorus-containing compound mass ratio are lower than 1:8 (such as comparative example 9 be 1:10)
Although when will appear battery core insulation resistance it is higher, the capacity of battery core plays lower, and cyclical stability is poor.This may be
Because (having elaborated t-carboxylic acid esters to battery core high temperature circulation stability in patent description caused by t-carboxylic acid esters content is not high enough
It is important).For example 55.5 ° of wetting abilities for demonstrating electrolyte of the contact angle of 9 electrolyte of comparative example are relatively on the weak side.
Comparative example 10
Electrolyte quota
By pivalic acid methyl esters and three (2,2,2- trifluoroethyl) phosphates with mass ratio for 96:1, which is configured without aqueous solvent, mixes
Object is closed, on the basis of the basic components of nonaqueous electrolytic solution, the content of the mixture is 48.5wt.%.EC is added, with non-aqueous solution electrolysis
On the basis of the basic components of liquid, content 25.0wt.%.Additive EMC is added, using the basic components of nonaqueous electrolytic solution as base
Standard, content 24.5wt.%.Additive VC, on the basis of the basic components of nonaqueous electrolytic solution, content 2.0wt.% is added.
It is slowly added to electrolytic salt LiPF6And cooled down, form nonaqueous electrolytic solution, the electrolytic salt LiPF6In the nonaqueous electrolytic solution
In concentration be 1.0mol/L.
Electrolyte flash-point is 22.2 DEG C.
Testing electrolyte by the contact angle measurement of model JC2000C1 is 45.5 ° to the contact angle of gel.
Battery makes with embodiment 1.
Battery performance test:When room temperature 1C discharges, energy density about 159.3Wh/kg is close to reach energy density ratings.
The insulation resistance of battery core is 1370 megaohms.By above-mentioned flexible-packed battery in 2.5~4.3V voltage range under 60 DEG C of environment temperatures
Interior 3C3D charge and discharge.First week discharge capacity is 13.7Ah, and energy density is 149.2Wh/kg for the first time.Capacity is after having recycled 35 weeks
13.0Ah, capacity retention ratio 95.1%, energy density 140.8Wh/kg.
It can be found that the electrical property in order to guarantee battery core is preferable such as comparative example 10, the content of t-carboxylic acid esters is improved as far as possible,
Reduce fluorine-containing and phosphorus-containing compound content.Although the battery core of battery core is functional, the flash-point of electrolyte is relatively inclined
It is low, there is security risk.The insulation resistance of prior battery core is relatively relatively low, equally also there is security risk.
Table 1 is the formula composition of embodiment 1~15 and comparative example 1~10
Table 2 is the embodiment of the present invention and comparative example physical function parameter test result
Table 3 is the embodiment of the present invention and comparative example battery performance parameter test result
Note:It is recycled n weeks in table 3, n=50 or 35 is specifically shown in specification embodiment.
The above, only be invention preferred embodiment, be not intended to limit the present invention in any form, although
The present invention has been disclosed as a preferred embodiment, and however, it is not intended to limit the invention, any person skilled in the art,
Without departing from the scope of the present invention, when the technology contents using the disclosure above make a little change or are modified to
With the equivalent embodiment of variation, but without departing from the technical solutions of the present invention, according to the technical essence of the invention to above
Any simple modification, equivalent change and modification made by embodiment, all of which are still within the scope of the technical scheme of the invention.
Claims (26)
1. a kind of lithium ion secondary battery, including anode, cathode, diaphragm and nonaqueous electrolytic solution;The nonaqueous electrolytic solution includes base
Plinth component and electrolytic salt, the basic components include solvent, it is characterised in that:The solvent includes such as formula (I) and/or such as formula
(II) fluorine-containing and phosphorous compound shown in, and the t-carboxylic acid esters as shown in formula (A):
Wherein, the R is selected from the alkyl that carbon atom number is 1~8;The R1、R2And R3At least one hydrogen atom is respectively selected from by fluorine
The alkyl or R that atom replaces and carbon atom number is 1~41、R2And R3Be respectively selected from least one hydrogen atom be replaced by fluorine atoms and
The alkoxy that carbon atom number is 1~4;The X1~X6Respectively indicate the alkoxy that carbon atom number is 1~8;Or X1~X6Table respectively
Show fluorine atom.
2. lithium ion secondary battery as described in claim 1, it is characterised in that:The R1、R2、R3Be respectively selected from trifluoromethyl,
2,2,2- trifluoroethyl, 1,1,1,3,3,3- hexafluoro isopropyl, perfluoro-t-butyl, seven fluorine normal-butyl of 2,2,3,3,4,4,4-, three
Fluorine methoxyl group, 2,2,2- trifluoro ethoxy, 2,2,2,3,3,3- hexafluoro isopropoxy, perfluor tert .-butoxy and 2,2,3,3,4,4,
At least one of seven fluorine n-butoxy of 4-.
3. lithium ion secondary battery as described in claim 1, it is characterised in that:The X1~X6It is respectively selected from fluorine atom, 2,2,
At least one of 2- trifluoro ethoxy and 2,2,2,3,3,3- hexafluoro isopropoxy.
4. lithium ion secondary battery as described in claim 1, it is characterised in that:Described fluorine-containing and phosphorus-containing compound is selected from three or three
Methyl fluoride phosphate, three (2,2,2- trifluoroethyl) phosphates, three (1,1,1,3,3,3- hexafluoro isopropyl) phosphates, three perfluors
T-butyl phosphate ester, three (seven fluorine normal-butyl of 2,2,3,3,4,4,4-) phosphates, bis trifluoromethyl phosphinic acid methyl ester, it is bis- (2,2,
2- trifluoroethyl) phosphinicacid ethyl ester, bis- (1,1,1,3,3,3- hexafluoro isopropyl) phosphinicacid ethyl esters, bis- (2,2,3,3,4,4,4-
Seven fluorine normal-butyls) phosphinicacid ethyl ester, five fluorine ring triphosphine nitrile of methoxyl group, five fluorine ring triphosphine nitrile of ethyoxyl, five fluorine ring three of positive propoxy
Phosphine nitrile, five fluorine ring triphosphine nitrile of isopropoxy, five fluorine ring triphosphine nitrile of n-butoxy, five fluorine ring triphosphine nitrile of isobutoxy, tert-butoxy
Five fluorine ring triphosphine nitriles, (2,2,2- trifluoro ethoxy) five fluorine phosphine nitrile fluorine ring triphosphine nitrile, (2,2,2,3,3,3- hexafluoro isopropoxy)
Five fluorine phosphine nitrile fluorine ring triphosphine nitriles, 2,4- dimethoxy -2,4,6,6- ptfe ring triphosphine nitrile, 2,4- diethoxy -2,4,6,6- four
Fluorine ring triphosphine nitrile, 2,4- bis- (2,2,2- trifluoro ethoxy) -2,4,6,6- tetrafluoro phosphine nitrile fluorine ring triphosphine nitrile and 2- methoxyl group -4- second
At least one of oxygroup -2,4,6,6- ptfe ring triphosphine nitrile.
5. lithium ion secondary battery as described in claim 1, it is characterised in that:The R is methyl or ethyl.
6. lithium ion secondary battery as described in claim 1, it is characterised in that:The t-carboxylic acid esters and fluorine-containing and phosphorous chemical combination
The mass ratio of object is 1:8~60:1.
7. lithium ion secondary battery as described in claim 1, it is characterised in that:The t-carboxylic acid esters and fluorine-containing and phosphorous chemical combination
The gross mass of object is the 2.0%~85.0% of the basic components gross mass.
8. lithium ion secondary battery as described in claim 1, it is characterised in that:The solvent further includes other solvents, described
Other solvents be selected from carbonic ester, sulfite, sulphonic acid ester, sulfone, ether, amide, organo-silicon compound, organoboron compound, nitrile and
At least one of ionic liquid.
9. lithium ion secondary battery as claimed in claim 8, it is characterised in that:The cation of the ionic liquid is selected from as follows
Structure:
R, R in above-mentioned nitrogenous compound structure1、R2、R3、R4、R5、R6Be independently selected from alkyl, alkenyl, alkynyl, phenyl,
Aryl;Or it is independently selected from the organic group of at least one of boracic, silicon, nitrogen, phosphorus, oxygen, sulphur, fluorine, chlorine, bromine and iodine element
Group;Described R, R1、R2、R3、R4、R5、R6It can be independent substituent group, be also possible to adjacent group joint cyclization.
10. lithium ion secondary battery as claimed in claim 8, it is characterised in that:The anion of the ionic liquid is selected from such as
Flowering structure:
11. the lithium ion secondary battery as described in claim 80, it is characterised in that:The quality of the ionic liquid is the base
The 0~99.5% of the gross mass of plinth component.
12. lithium ion secondary battery as claimed in claim 8, it is characterised in that:Other solvents be selected from ethylene carbonate,
Fluoroethylene carbonate, propylene carbonate, butylene carbonate and carbonic acid Asia enester, methyl carbonic acid acrylic ester, ethyl carbonate propylene
Ester, methyl carbonic acid phenol ester, ethylene carbonate, halogenated ethylene carbonate, propene carbonate, butylene, dimethyl carbonate,
Diethyl carbonate, methyl ethyl carbonate, methyl propyl carbonate, hexyl acetate, isobutyl acetate, propyl isobutyrate, 1,3- propylene glycol two
Pivalate, two pivalate of 1,4- butanediol, ethylene sulfite, propylene sulfite, butylene sulfite, sulfurous acid two
Methyl esters, sulfurous acid diethyl ester, sulfolane, dimethyl sulfoxide, second methyl sulfoxide, 1,3- propane sulfonic acid ester, 1,4- butyl sultone, dioxy
Penta ring, dimethoxy propane, dimethyldimethoxysil,ne, special valeronitrile, valeronitrile, 2,2- methyl pentane nitrile, N- methyl-N- butyl
At least one in bis- (trimethyl fluoride sulfonyl) inferior amine salts of piperidines and bis- (trimethyl fluoride sulfonyl) inferior amine salts of N- Methyl-N-propyl pyrrolidines
Kind.
13. lithium ion secondary battery as claimed in claim 8, it is characterised in that:The carbonic ester include cyclic carbonate and
Linear carbonate;The cyclic carbonate is selected from ethylene carbonate, fluoroethylene carbonate, propylene carbonate, butylene carbonate
And at least one of carbonic acid Asia enester;The linear carbonate is in dimethyl carbonate, diethyl carbonate and methyl ethyl carbonate
It is at least one.
14. lithium ion secondary battery as claimed in claim 8, it is characterised in that:The quality of the carbonic ester is the basis
The 0~99.5% of the gross mass of component.
15. lithium ion secondary battery as described in claim 1, it is characterised in that:The electrolytic salt includes alkali metal salt, institute
Stating alkali metal salt includes fluorine-containing alkali metal lithium salts and/or fluorine-containing alkali metal sodium salt;The alkali metal lithium salts is selected from LiPF6、
LiBF4、LiN(SO2CF3)2、LiN(SO2C2F5)2、LiN(SO2F)2、LiPO2F2、LiCF3SO3、LiC(SO2CF3)3、LiPF3
(CF3)3、LiPF3(C2F5)3、LiPF3(iso-C3F7)3、LiPF5(iso-C3F7)、LiB(C2O4)2、LiBF2(C2O4) and
Li2B12F12At least one of;The alkali metal sodium salt is selected from NaPF6、NaBF4、NaN(SO2CF3)2、NaN(SO2C2F5)2、NaN
(SO2F)2、NaPO2F2、NaCF3SO3、NaC(SO2CF3)3、NaPF3(CF3)3、NaPF3(C2F5)3、NaPF3(iso-C3F7)3、
NaPF5(iso-C3F7)、NaBF2(C2O4) and Na2B12F12At least one of.
16. lithium ion secondary battery as claimed in claim 15, it is characterised in that:In the nonaqueous electrolytic solution, the alkali gold
The concentration for belonging to salt is 0.5mol/L~3.0mol/L.
17. lithium ion secondary battery as described in claim 1, it is characterised in that:The basic components further include additive;Institute
Stating additive includes at least one in film for additive, anti-overcharge additive, flame-retardant additive, conductive additive and wetting additive
Kind.
18. lithium ion secondary battery as claimed in claim 17, it is characterised in that:The film for additive includes organic film forming
Additive and inorganic film for additive;Organic film for additive is selected from ionic liquid, sulfuric ester, sulfite, sulfone, Asia
Sulfone, sulphonic acid ester, carbonic ester, halocarbonate, halogenated carboxylic ester, unsaturated carbon acid ester containing double bond, nitrile, crown ether and organic boride
At least one of;The inorganic film for additive is selected from LiBOB, LiODBF, NaBOB, NaODBF, Li2CO3、Na2CO3、K2CO3
And NH4At least one of I.
19. lithium ion secondary battery as claimed in claim 17, it is characterised in that:The anti-overcharge additive is selected from oxidation-
Reduction is to additive and electropolymerization additive.
20. lithium ion secondary battery as claimed in claim 17, it is characterised in that:The flame-retardant additive is selected from non-halogenated phosphorus
At least one of acid esters, amide and ionic liquid.
21. lithium ion secondary battery as claimed in claim 17, it is characterised in that:The conductive additive is matched including cation
Body compound, anion ligand compound, neutral ligand compound, amine, crown ether, cryptand compound, fluoro-alkyl boronation
At least one of object, alkyl boron compounds and azepine ether.
22. lithium ion secondary battery as claimed in claim 17, it is characterised in that:The wetting additive includes containing aryl
Carbonic ester or carbon atom quantity are the carbonic ester and tertiary ammonium surfactant of 1~20 alkyl.
23. lithium ion secondary battery as claimed in claim 17, it is characterised in that:The quality of the additive is the basis
The 0~20.0% of component gross mass.
24. lithium ion secondary battery as described in claim 1, it is characterised in that:The active material of the anode is selected from lithium nickel
Cobalt manganese composite oxide, sodium cobalt-nickel-manganese oxide compound, sodium nickel/cobalt composite oxide, lithium nickel cobalt aluminium composite oxide, lithium manganese nickel
Composite oxides, olivine-type lithium iron phosphate oxide, lithium and cobalt oxides, sodium cobalt/cobalt oxide, lithium manganese oxide and sodium manganese oxide
At least one of.
25. lithium ion secondary battery as described in claim 1, it is characterised in that:The active material of the cathode be selected from graphite,
Carbonaceous mesophase spherules, amorphous carbon, lithium titanium oxygen compound, lithium oxyvanadium compound, silica-base material, tin-based material and oxo transition metal
At least one of compound.
26. lithium ion secondary battery as described in claim 1, it is characterised in that:The diaphragm is selected from polyolefin fusion drawn
Diaphragm;Or the diaphragm is at least one in PET (polyethylene terephthalate), Kynoar, aramid fiber and polyamide
Kind is the diaphragm of substrate;Or the diaphragm of polyolefin is coated on high softening-point porous matrix material.
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CN111430798A (en) * | 2020-04-03 | 2020-07-17 | 珠海冠宇电池股份有限公司 | Electrolyte, preparation method thereof and lithium ion battery |
CN111952666A (en) * | 2020-07-08 | 2020-11-17 | 深圳市比克动力电池有限公司 | Additive for battery electrolyte, lithium ion battery electrolyte and lithium ion battery |
CN115863655A (en) * | 2023-02-27 | 2023-03-28 | 江门市科恒实业股份有限公司 | High-temperature-resistant lithium cobalt oxide positive electrode material and preparation method thereof |
CN116314595A (en) * | 2023-05-15 | 2023-06-23 | 蔚来电池科技(安徽)有限公司 | Secondary battery and device |
CN117175017A (en) * | 2023-08-10 | 2023-12-05 | 山东泰一新能源股份有限公司 | Low-temperature electrolyte for lithium battery |
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CN108933277B (en) | 2022-03-18 |
CN114512723B (en) | 2024-04-09 |
CN114512723A (en) | 2022-05-17 |
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